[1] Oldroyd G, Leyser O. A plant's diet, surviving in a variable nutrient environment. Science, 2020,368: eaba0196 [2] Du EZ, Terrer C, Pellegrini A, et al. Global patterns of terrestrial nitrogen and phosphorus limitation. Nature Geoscience, 2020, 13: 221-226 [3] Vitousek PM, Porder S, Houlton BZ, et al. Terrestrial phosphorus limitation: Mechanisms, implications, and nitrogen-phosphorus interactions. Ecological Applications, 2010, 20: 5-15 [4] Schleuss PM, Widdig M, Heintz-Buschart A, et al. Interactions of nitrogen and phosphorus cycling promote P acquisition and explain synergistic plant-growth responses. Ecology, 2020, 101: 1-14 [5] 张亚伟, 孙海龙, 郑鸿权, 等. 施肥对水曲柳林木叶片SPAD值的影响. 森林工程, 2020, 36(5): 34-39 [6] 卫星杓, 戴腾飞, 刘诗琦, 等. 施肥对无患子叶片养分动态及产量的影响. 南京林业大学学报: 自然科学版, 2018, 42(5): 17-24 [7] 邓磊, 朱春云, 于世川, 等. 祁连山青海云山中龄林混交度对细根形态特征的影响. 林业科学, 2020, 56(1): 191-200 [8] McCormack ML, Dickie IA, Eissenstat DM, et al. Redefining fine roots improves understanding of below-ground contributions to terrestrial biosphere processes. New Phytologist, 2015, 207: 505-518 [9] Comas LH, Eissenstat DM. Liking fine root traits to maximum potential growth rate among 11 mature tempe-rate tree species. Functional Ecology, 2004, 18: 388-397 [10] Wurzburger N, Wright SJ. Fine-root responses to fertilization reveal multiple nutrient limitation in a lowland tropical forest. Ecology, 2015, 96: 2137-2146 [11] 于立忠, 丁国泉, 史建伟, 等. 施肥对日本落叶松人工林细根直径、根长和比根长的影响. 应用生态学报, 2007, 18(5): 957-962 [12] 刘金梁, 梅莉, 谷加存, 等. 内生长法研究施氮肥对水曲柳和落叶松细根生物量和形态的影响. 生态学杂志, 2009, 28(1): 1-6 [13] 钟全林, 程栋梁, 胡松竹, 等. 刨花楠和华东润楠叶绿素含量分异特征及与净光合速率的关系. 应用生态学报, 2009, 20(2): 271-276 [14] 裴盼, 钟全林, 程栋梁, 等. 氮磷叶片喷施对未郁闭刨花楠人工幼林生长的影响. 应用与环境生物学报, 2016, 22(5): 831-838 [15] 王艳, 钟全林, 徐朝斌, 等. 短期氮磷配施对刨花楠细根形态及其土壤微生物的影响. 生态学报, 38(7): 2271-2278 [16] 邹宇星, 钟全林, 游雅玲, 等. 短期氮-水处理对刨花楠幼苗细根根序形态的影响. 应用生态学报, 2018, 29(7): 2323-2329 [17] 费玲, 钟全林, 程栋梁, 等. 氮磷喷施对刨花楠叶片养分再吸收效率的影响. 应用与环境生物学报, 2015, 21(2): 295-300 [18] 鲍士旦. 土壤农化分析. 第三版. 北京: 中国农业出版社, 2000: 20-197 [19] Aerts R, Chapin FS. The mineral nutrition of wild plants revisited: A re-evaluation of processes and patterns. Advances in Ecological Research, 1999, 30: 1-67 [20] Li FL, Hu H, McCormlack ML, et al. Community-level economics spectrum of fine-roots driven by nutrient limitations in subalpine forests. Journal of Ecology, 2019, 107: 1238-1249 [21] Hu B, Chu CC. Nitrogen-phosphorus interplay: Old story with molecular tale. New Phytologist, 2019, 225: 1455-1460 [22] Yuan ZY, Chen HY. A global analysis of fine root production as affected by soil nitrogen and phosphorus. Proceedings of the Royal Society B: Biological Sciences, 2012, 279: 3796-3802 [23] 涂利华, 胡庭兴, 张健, 等. 模拟氮沉降对华西雨屏区苦竹林细根特性和土壤呼吸的影响. 应用生态学报, 2010, 21(10): 2472-2478 [24] Ostonen I, Lõhmus K, Lasn R. The role of soil conditions in fine root ecomorphology in Norway spruce (Picea abies (L.) Karst.). Plant and Soil, 1999, 208: 283-292 [25] Wells CE, Glenn DM, Eissenstat DM. Changes in the risk of fine-root mortality with age: A case study in peach, Prunus persica (Rosaceae). American Journal of Botany, 2002, 89: 79-87 [26] Taylor BN, Strand AE, Cooper ER, et al. Root length, biomass, tissue chemistry and mycorrhizal colonization following 14 years of CO2 enrichment and 6 years of N fertilization in a warm temperate forest. Tree Physiology, 2014, 34: 955-965 [27] 马玉珠, 钟全林, 靳冰洁, 等. 中国植物细根碳、氮、磷化学而计量学的空间变化及其影响因子. 植物生态学报, 2015, 39(2): 159-166 [28] Freschet GT, Valverde-Barrantes OJ, Tucker CM, et al. Climate, soil and plant functional types as drivers of global fine-root trait variation. Journal of Ecology, 2017, 105: 1182-1196 [29] Shi MJ, Fisher JB, Brzostek ER, et al. Carbon cost of plant nitrogen acquisition: Global carbon cycle impact from an improved plant nitrogen cycle in the Community Land Model. Global Change Biology, 2016, 22: 1299-1314 |